Integrated polarimeter in an optical line system

ABSTRACT

A management system for an optical line system includes one or more processors and memory storing instructions that, when executed, cause the one or more processors to receive State of Polarization (SOP) measurements from one or more optical components in the optical line system, wherein the SOP measurements are taken while traffic-bearing channels are operating, and monitor health of one or more fibers based on the SOP measurements. The health can include detection and/or localization of SOP transients.

CROSS-REFERENCE TO RELATED APPLICATION(S)

The present patent/application is a continuation of U.S. patent application Ser. No. 16/931,683, filed Jul. 17, 2020 (now U.S. Pat. No. 11,209,315 with an issue date of Dec. 28, 2021), and entitled “INTEGRATED POLARIMETER IN AN OPTICAL LINE SYSTEM,” which was a continuation of U.S. patent application Ser. No. 16/193,246, filed Oct. 16, 2018 (now U.S. Pat. No. 10,746,602 with an issue date of Jul. 18, 2020), and entitled “INTEGRATED POLARIMETER IN AN OPTICAL LINE SYSTEM,” which was a continuation of U.S. patent application Ser. No. 15/177,982, filed Jun. 9, 2016 (now U.S. Pat. No. 10,161,798 with an issue date of Dec. 25, 2018), and entitled “INTEGRATED POLARIMETER IN AN OPTICAL LINE SYSTEM,” the contents of each are incorporated herein by reference in their entirety.

FIELD OF THE DISCLOSURE

The present disclosure generally relates to fiber optic systems and methods. More particularly, the present disclosure relates to an integrated polarimeter in an optical line system.

BACKGROUND OF THE DISCLOSURE

As bandwidth continues to grow, capacity is being stretched in fiber optic networks (Wavelength Division Multiplexing (WDM), optical line systems, etc.). Various advanced techniques are used to provide additional bandwidth including advanced coherent modulation techniques, polarization multiplexing, flexible grid spacing, and the like in optical line systems. With these advanced techniques, optical line systems suffer new degrees of susceptibility to transients on a time varying optical channel, including polarization transients, etc. As described herein, a State of Polarization (SOP) transient source causes an SOP transient which is anything that causes quick changes in the SOP of signals on an optical fiber. Coherent optical line systems are configured to track SOP changes as part of normal operation, but when quick SOP transients occur, these can be outside the tracking ability, leading to errors, loss of framing, etc. Example SOP transient sources can include, without limitation, external vibrations (e.g., bridges, roads, railroads, wind, etc.), bad splices on the optical fiber, weather (e.g., lightning, wind, etc.), or the like. Usually, SOP transient sources behave unpredictably and from unknown locations in the fiber. Further, SOP transient sources can be time specific, seasonal, etc. Thus, it is important in optical line systems to have some technique for real-time, in-service measurement. SOP transients can be particularly problematic with coherent transmission, and especially difficult to localize/isolate given their nature in general. An application using a polarimeter with an optical line system for SOP transient localization is described in commonly-assigned U.S. patent application Ser. No. 14/865,802 filed Sep. 25, 2015, and entitled “SYSTEMS AND METHODS USING A POLARIMETER TO LOCALIZE STATE OF POLARIZATION TRANSIENTS ON OPTICAL FIBERS,” the contents of which are incorporated by reference.

Polarimeters are polarization measurement devices configured to measure the polarization state of an optical signal. Conventionally, in optical line systems (e.g., WDM, Dense WDM, etc.), polarimeters are external test devices which connect to the optical line system, i.e., polarimeters are not integrated devices. Accordingly, conventional polarimeters do not operate in-service, i.e., with traffic-bearing signals active on the optical line system. Further, conventional polarimeters rely on free space optics which is not amenable to integration with fiber components (i.e., non-free space optics). Conventional polarimeters require special design of bulk free space optics components and/or special coupling functions of an optical fiber leading to costly and bulky implementations. Finally, conventional polarimeters are cost prohibitive for optical line system applications as well as complex providing vast more information than necessary for such optical line system applications, i.e., only SOP tracking is required to monitor the health of an optical fiber.

It would be advantageous to provide a polarimeter integrated with an optical line system optimized to provide functionality necessary for monitoring the health of the optical line system.

BRIEF SUMMARY OF THE DISCLOSURE

In an embodiment, a polarimeter includes a Polarization Maintaining (PM) coupler with an input configured to receive input light and split the input light to a first output and a second output; a first PM fiber coupled to the first output; a second PM fiber coupled to the second output; a first polarization device coupled to the first PM fiber; a second polarization device coupled to the second PM fiber; and a plurality of detectors coupled to the first polarization device and the second polarization device, wherein outputs i₁, i₂, i₃, i₄ are determined based on outputs of the plurality of detectors, the outputs i₁, i₂, i₃, i₄ are linear projections of corresponding Stokes Parameters of the input light. The input light can be dual polarization light. The PM coupler can be configured to split the input light into two identical signals on the first output and the second output, and wherein the identical signal on the second PM fiber is rotated by 45°. The rotation by 45° can be at an output of the PM coupler. The rotation by 45° can be at an input to the first polarization device and the second polarization device.

The first polarization device and the second polarization device can each be a Polarization Beam Splitter (PBS) with two corresponding outputs, and wherein the plurality of detectors can be four detectors each coupled to an output of the corresponding PBS such that the outputs i₁, i₂, i₃, i₄ are determined from each of the four detectors. The first polarization device and the second polarization device can each be a polarizer, and the polarimeter can further include an input detector prior to the PM coupler configured to detect total power of the input light, wherein the plurality of detectors are two detectors each coupled to an output of the corresponding polarizer such that the outputs i₁, i₃ are determined from each of the two detectors and the outputs i₂, i₄ are derived by subtracting the corresponding outputs i₁, i₃ from the total power of the input light. The input light can have 100% Degree of Polarization (DOP). A wavelength of the input light can be outside of the C-band, greater than 1500 nm to avoid Raman pump lasers, and different from wavelengths for Optical Supervisory Channels (OSCs).

In another embodiment, a method of operating a polarimeter includes receiving input light at a Polarization Maintaining (PM) coupler and splitting the input light to a first output and a second output; receiving the first output at a first polarization device coupled to a first PM fiber which is coupled to the PM coupler; receiving the second output at a second polarization device coupled to a second PM fiber which is coupled to the PM coupler; detecting light with a plurality of detectors coupled to the first polarization device and the second polarization device; and determining outputs i₁, i₂, i₃, i₄ based on outputs of the plurality of detectors, the outputs i₁, i₂, i₃, i₄ are linear projections of corresponding Stokes Parameters of the input light.

In a further embodiment, a polarimeter include a Polarization Maintaining (PM) coupler with an input configured to receive input light and split the input light to a first output and a second output; a detector prior to the PM coupled configured to detect total power of the input light; a first PM fiber coupled to the first output; a second PM fiber coupled to the second output; a first polarizer coupled to the first PM fiber; a second polarizer coupled to the second PM fiber; and a first detector coupled to the first polarizer and a second detector coupled to the second polarizer, wherein outputs i₁, i₂, i₃, i₄ are determined based on outputs of the first detector, the second detector, and the total power, the outputs i₁, i₂, i₃, i₄ are linear projections of corresponding Stokes Parameters of the input light.

In a further embodiment, a polarimeter system integrated into an optical line system includes a transmitter coupled to a transmit filter communicatively coupled to an output port in an optical line device, wherein the transmitter is configured to generate a polarization probe signal, and wherein a wavelength of the polarization probe signal is configured to operate in-service with traffic-bearing channels on the output port; and a polarimeter receiver coupled to a receive filter communicatively coupled to an input port in the optical line device, wherein the polarimeter receiver is configured to vary arrangement of input light of a corresponding polarization probe signal from the receive filter and to measure various outputs of the varied arrangement to derive a measurement of State of Polarization (SOP) of the input light. The polarimeter system can be located at a first node in the optical line system, and wherein the polarimeter system can further include at a second node, opposite the first node and communicatively coupled thereto by two fibers: an amplifier coupled to a second receive filter in a second optical line device, wherein the amplifier is configured to receive the polarization probe signal from the second receive filter, amplify the polarization probe signal, and loop back the polarization probe signal to the polarimeter receiver via a second transmit filter. The optical line device can include one or more of a Raman amplifier module, an Erbium Doped Fiber Amplifier (EDFA) module, an Optical Supervisory Channel (OSC) module, an Optical Time Domain Reflectometer (OTDR) module, a modem, and a pluggable module adapted to plug into any of the foregoing modules. The polarimeter system can operate continuously while the optical line system is in-service to collect SOP data over time and to detect fast SOP transients on a specific span in the optical line system.

The polarimeter receiver can be implemented with a plurality of passive fiber optic components to provide the varied arrangement and a plurality of detectors to measure the various outputs. The plurality of passive fiber optic components can include a Polarization Maintaining (PM) coupler configured to receive the input light, PM fiber coupled to outputs of the PM coupler, a 45° alignment associated with one output of the PM coupler, and Polarization Beam Splitters (PBSs) coupled to four detectors for measuring i₁, i₂, i₃, and i₄. The plurality of passive fiber optic components can include a Polarization Maintaining (PM) coupler configured to receive the input light, PM fiber coupled to outputs of the PM coupler, a 45° alignment associated with one output of the PM coupler, polarizers coupled to two detectors for measuring i₁ and i₃, and another detector coupled to an input to measure total input power for estimation of i₂ and i₄ based on the total power and the measurement of i₁ and i₃. The optical line device can include the polarimeter system and an Optical Time Domain Reflectometer (OTDR), wherein the transmitter is shared between the polarimeter system and the OTDR based on configuration. The wavelength of the polarization probe signal can be outside of the C-band, greater than 1500 nm to avoid Raman pump lasers, and different from wavelengths for Optical Supervisory Channels (OSCs).

In another further embodiment, a polarimeter method with a polarimeter integrated into an optical line system includes providing a transmitter coupled to a filter communicatively coupled to an output port in an optical line device, wherein the transmitter is configured to generate a polarization probe signal, and wherein a wavelength of the polarization probe signal is configured to operate in-service with traffic-bearing channels on the output port; and providing a polarimeter receiver coupled to a filter communicatively coupled to an input port in the optical line device, wherein the polarimeter receiver is configured to vary arrangement of input light of a corresponding polarization probe signal from the filter and to measure various outputs of the varied arrangement to derive a measurement of State of Polarization (SOP) of the input light. The polarimeter system can be located at a first node in the optical line system, and wherein the polarimeter method can further include at a second node, opposite the first node and communicatively coupled thereto by two fibers: providing an amplifier coupled to a second receive filter in a second optical line device, wherein the amplifier is configured to receive the polarization probe signal from the second receive filter, amplify the polarization probe signal, and loop back the polarization probe signal to the polarimeter receiver via a second transmit filter. The optical line device can include one or more of a Raman amplifier module, an Erbium Doped Fiber Amplifier (EDFA) module, an Optical Supervisory Channel (OSC) module, an Optical Time Domain Reflectometer (OTDR) module, a modem, and a pluggable module adapted to plug into any of the foregoing modules. The polarimeter system can operate continuously while the optical line system is in-service to collect SOP data over time and to detect fast SOP transients on a specific span in the optical line system.

The polarimeter receiver can be implemented with a plurality of passive fiber optic components to provide the varied arrangement and a plurality of detectors to measure the various outputs. The plurality of passive fiber optic components can include a Polarization Maintaining (PM) coupler configured to receive the input light, PM fiber coupled to outputs of the PM coupler, a 45° alignment associated with one output of the PM coupler, and Polarization Beam Splitters (PBSs) coupled to four detectors for measuring i₁, i₂, i₃, and i₄. The plurality of passive fiber optic components can include a Polarization Maintaining (PM) coupler configured to receive the input light, PM fiber coupled to outputs of the PM coupler, a 45° alignment associated with one output of the PM coupler, polarizers coupled to two detectors for measuring i₁ and i₃, and another detector coupled to an input to measure total input power for estimation of i₂ and i₄ based on the total power and the measurement of i₁ and i₃. The optical line device can include the polarimeter system and an Optical Time Domain Reflectometer (OTDR), wherein the transmitter is shared between the polarimeter system and the OTDR based on configuration. The wavelength of the polarization probe signal can be outside of the C-band, greater than 1500 nm to avoid Raman pump lasers, and different from wavelengths for Optical Supervisory Channels (OSCs).

In yet another further embodiment, an optical line device configured to operate in an optical line system includes optical line components communicatively coupled to an output port via a transmit filter and an input port via a receive filter; and a polarimeter system including a transmitter coupled to the transmit filter, wherein the transmitter is configured to generate a polarization probe signal, and wherein a wavelength of the polarization probe signal is configured to operate in-service with traffic-bearing channels on the output port; and a polarimeter receiver coupled to the receive filter, wherein the polarimeter receiver is configured to vary arrangement of input light of a corresponding polarization probe signal from the receive filter and to measure various outputs of the varied arrangement to derive a measurement of State of Polarization (SOP) of the input light. The optical line components can be configured to perform one or more of a Raman amplifier, an Erbium Doped Fiber Amplifier (EDFA) module, an Optical Supervisory Channel (OSC) module, an Optical Time Domain Reflectometer (OTDR) module, a modem, and a pluggable module adapted to plug into any of the foregoing modules.

BRIEF DESCRIPTION OF THE DRAWINGS

The present disclosure is illustrated and described herein with reference to the various drawings, in which like reference numbers are used to denote like system components/method steps, as appropriate, and in which:

FIG. 1 is a network diagram of an optical network with two nodes interconnected by fibers each contained in a bundle;

FIG. 2 is a block diagram of an optical line device with a polarimeter integrated therein;

FIG. 3 is a block diagram of an optical line device with an amplifier for operation with the optical line device of FIG. 2 in a loop-backed polarimeter configuration;

FIG. 4 is a block diagram of an optical line device which is a Raman amplifier with the polarimeter integrated therein;

FIG. 5 is a block diagram of an optical line device which can be a pluggable module or the like with the polarimeter integrated therein sharing components with an OTD R;

FIG. 6 is a block diagram of a Division of Amplitude Polarimeter (DOAP) which may be used for the integrated polarimeter;

FIG. 7 is a block diagram of a novel, low-cost fiber optics-based integrated polarimeter that can be used with and integrated into components of the optical line system with a 45° alignment coupled to a Polarization Maintaining (PM) coupler;

FIG. 8 is a block diagram of another integrated polarimeter similar to the integrated polarimeter of FIG. 7 with the 45° alignment moved to a Polarization Beam Splitter;

FIG. 9 is a block diagram of yet another integrated polarimeter replacing the Polarization Beam Splitters from the integrated polarimeter of FIG. 7 with Polarizers and adding a total power photodetector tapped from the input of the PM coupler;

FIG. 10 is a block diagram of yet another integrated polarimeter similar to the integrated polarimeter of FIG. 9 with the 45° alignment moved to a Polarizer;

FIG. 11 is a 2D graph of values of the electrical outputs i₁, i₂, i₃, i₄ from the DOAP of FIG. 6 and the integrated polarimeter of FIGS. 7-10 ;

FIG. 12 are graphs in a table illustrating example measurements with the integrated polarimeter for linearly polarized light on a slow axis, polarization transforming between 45° linear polarization and circular polarization, and randomly rotating polarization with a polarization scrambler;

FIG. 13 are graphs of measurements taken by the integrated polarimeter relative to a commercial, external polarimeter to detect a mechanical shock applied to the optical line system;

FIG. 14 are graphs of measurements taken by the integrated polarimeter relative to a commercial, external polarimeter to detect hot air applied to the optical line system;

FIG. 15 is a network diagram of an example setup for a two-fiber mode in a loopback configuration with the integrated polarimeter to localize the SOP transients.

DETAILED DESCRIPTION OF THE DISCLOSURE

Again, in various embodiments, the present disclosure relates to an integrated polarimeter in an optical line system. The integrated polarimeter provides the functionality needed in optical line applications including detection of SOP transients, localization of the SOP transients to either an approximate distance or a span, overall health monitoring of the optical fiber, and the like. The integrated polarimeter is designed with “off-the-shelf” passive fiber optic components, lending itself to integration with existing components in the optical line system, such as in a line card, line module, pluggable module, hardware device, or the like. The integrated polarimeter includes a source laser and various embodiments for a detector based on Polarization Maintaining (PM) couplers and fibers, polarizers, and Polarization Beam Splitters (PBSs) coupled to detectors. Accordingly, the integrated polarimeter can collect real-time SOP transient data over individual spans in an optical network, in real-time while operating in-service without disrupting traffic-bearing channels. Such real-time operation provides operators a wealth of data which can be used for various network optimization techniques such as monitoring historical data to determine optimum modem types and performance on particular spans, to determine decisions about restoration events, to troubleshoot and identify fast SOP transients to specific spans or location, and the like.

Optical Line System

Referring to FIG. 1 , in an embodiment, a network diagram illustrates an optical network 10 with two nodes 12, 14 interconnected by fibers 16, 18 each contained in a bundle 20. The optical nodes 12, 14 connected to one another over the fibers 16, 18 can be referred to as an optical line system and represents a single span. Of course, those of ordinary skill in the art will recognize the optical network 10 can include additional nodes, fibers, bundles, spans, optical amplifier sites, add/drop sites, etc. The nodes 12, 14 can be any type of optical network element including, without limitation, Wavelength Division Multiplexing (WDM) terminals, Reconfigurable Optical Add/Drop Multiplexers (ROADMs), switches, routers, cross-connects, etc. In an embodiment, the nodes 12, 14 have optical transceivers, transponders, or modems (collectively referred to herein as “modems”) to provide transmission of traffic-bearing channels. The nodes 12, 14 can further include optical amplifiers such as Erbium Doped Fiber Amplifiers (EDFAs), Raman Amplifiers, or the like. The nodes 12, 14 can include multiplexer and demultiplexer components such as splitters, combiners, Wavelength Selective Switches, etc. to perform WDM of multiple traffic-bearing channels from multiple modems. Also, the nodes 12, 14 can include various other components such as Optical Supervisory Channels (OSCs) for management communication between optical nodes such as optical amplifiers, Optical Time Domain Reflectometers (OTDR) to measure back reflections over the fibers 16, 18, Raman amplifiers, and the like.

The various aforementioned components in the nodes 12, 14 can be physically realized in hardware components in a network element forming the node 12, 14. The hardware components can be included in line cards, line modules, pluggable modules, “pizza boxes” which are small-form-factor units such as 1-2 Rack Units (RU) high, or the like. The hardware components are generally optically connected to one another for ultimate transmission and reception over the fibers 16, 18. As described herein, an optical line device is a hardware device which is part of the nodes 12, 14 and integrated therein. Examples of optical line devices can include Raman amplifier modules, EDFA amplifier modules, OSC modules, OTDR modules, modems, and the like. In various embodiments, the integrated polarimeter is part of an optical line device in the nodes 12, 14 capable of in-service polarimeter measurements of the fibers 16, 18 while the traffic-bearing channels are operating thereon. The integrated polarimeter is physically integrated with the optical line device as well as controlled by software in the nodes 12, 14 and the overall optical line system, providing measurements and alerts to the nodes 12, 14 and to associated management systems, control planes, etc. Those of ordinary skill in the art will recognize various different types of optical line systems and optical line devices are known, the optical network 10 is described for illustration purposes, and the integrated polarimeter contemplates integration with any type of optical line system and optical line device.

The modems can include Non-Return-to-Zero (NRZ), duobinary, quadrature amplitude modulation (QAM), differential phase shift keying (DPSK), differential quadrature phase shift keying (DQPSK), orthogonal frequency-division multiplexing (OFDM), polarization multiplexing with any of the foregoing, and any other type of optical modulation and detection technique. Importantly, as the modems utilize advanced coherent modulation/demodulation techniques, they are susceptible to SOP transients. In coherent optical systems, optical receivers in the modems must track the SOP of the optical signal. In some instances, very fast SOP transients have been known to occur, which can impair receiver performance or in the worst case cause bit errors. Debugging each of these links after the fact is very time-consuming. Thus, the integrated polarimeter can provide significant operational data related to SOP transients on the fibers 16, 18 which is useful with advanced coherent modulation/demodulation techniques. The integrated polarimeter provides real-time, in-service SOP transient tracking. With the integrated polarimeter in multiple spans in the optical network 10 can complement OTDR data to give the network operator a complete view of the quality of the fibers 16, 18 in real-time.

The nodes 12, 14 can communicate to a management system such as a Network Management System (NMS), an Element Management System (EMS), a Path Computation Element (PCE), a Software Defined Networking (SDN) controller, a control plane, or the like. SOP transient statistics from the integrated polarimeter can be provided to the management system and used for 1) troubleshooting to identify and localize the cause of errors, 2) making decisions about what types of modems to deploy or in the case on programmable modems, which type of configuration (modulation scheme, spectrum amount, etc.), 3) optimize the performance of modems based on the required SOP tracking speed of the fibers 16, 18, 4) making decisions when rerouting traffic during network restoration (e.g., avoiding problematic spans at the time of rerouting), and the like.

Integrated Polarimeter in an Optical Line Device/System

Referring to FIGS. 2-5 , in embodiments, block diagrams illustrate a polarimeter configuration embedded in optical line devices 30, 32, 34, 36. FIG. 2 illustrates an optical line device 30 with a polarimeter 40 integrated therein, FIG. 3 illustrates an optical line device 32 with an amplifier 42 for operation with the optical line device 30 in a loop-backed polarimeter configuration, FIG. 4 illustrates an optical line device 34 which is a Raman amplifier with the polarimeter 40 integrated therein, and FIG. 5 illustrates an optical line device 36 which can be a pluggable module or the like with the polarimeter 40 integrated therein sharing components with an OTDR 44. Again, FIGS. 2-5 are embodiments of integration of the polarimeter 40 with optical line systems and the like; those of ordinary skill in the art will recognize the integrated polarimeter contemplates integration with any optical line system, optical line device, etc. to provide real-time, in-service operation.

In FIG. 2 , the optical line device 30 includes the polarimeter 40 integrated therein, supporting the transmission of a polarimeter probe signal on the fiber 16 and reception of a corresponding polarimeter probe signal on the fiber 18. In an embodiment, the optical line device 30 can be used at various nodes in the optical network 10 to support polarimeter probe signals on both the fibers 16, 18. In FIG. 3 , the optical line device 32 includes the amplifier 42 integrated therein which is configured to receive the polarimeter probe signal on the fiber 16, to amplify the polarimeter probe signal, and to loop back the polarimeter probe signal on the fiber 18. Thus, in one embodiment, the optical line device 30 can be at opposing nodes 12, 14 to support a single polarimeter probe signal on each fiber 16, 18, and in another embodiment, the optical line device 30 can be at the node 12 and the optical line device 32 can be at the node 14 to support a loopback of the same probe signal. The loopback, as described herein in FIG. 15 , can provide additional details for finer granularity of localization of SOP transients. In another embodiment, the optical line device 30 can be at opposing nodes 12, 14 to support a single polarimeter probe signal which each propagates on the fiber 16, 18, in opposite directions. Variously, the transmitter for the single polarimeter probe signal can be tunable. Where the single polarimeter probe signals from opposing optical line devices 30 counter-propagate, the tunable transmitter can tune to different wavelengths for each of the polarization probe signals. In this manner, a virtual loopback is achieved as polarimeter data is obtained from both the opposing optical line devices 30 and this polarimeter data can be used for fault localization in a similar manner as the physical loopback with the optical line device 32.

The optical line devices 30, 32 include various optical line components 50, 52 in addition to the polarimeter 40 and the amplifier 42. The optical line components 50 are shown transmitting on the fiber 16 whereas the optical line component 52 are shown receiving from the fiber 18. The optical line components 50, 52 can be anything integrated within the optical line system such as EDFA amplifiers, Raman amplifiers, OSCs, OTDRs, modems or transceivers, WSSs, or the like. The optical line devices 30, 32 include filters 54, 56 for multiplexing and demultiplexing the polarimeter probe signal with WDM signals, OSC signals, OTDR signals, Raman pumps, and the like. In the optical line device 50, the filter 54 configured to combine an output of the polarimeter 54 with an output of the optical line components 50 and the filter 56 is configured to split the polarimeter probe signal to the polarimeter 40 and the other signals (WDM signals, OSC signals, OTDR signals, Raman pumps, etc.) to the optical line components 52. Similarly, in the optical line device 32, the filter 56 splits the polarimeter probe signal to the amplifier 42 separate from the other signals which are provided to the optical line components 52 and the filter 54 combines an output of the amplifier 42, i.e., the amplified polarization probe signal, with outputs of the optical line components 50. The optical line device 32 is illustrated herein with the amplifier 42, but in other embodiments, the amplifier 42 may be omitted in lieu of a simple connection forming the loopback function in the optical line device 32. This may be used in cases where amplification is not required for the polarization probe signal to traverse both of the fibers 16, 18, such as in shorter spans.

With respect to integration, the optical line devices 30, 32 can be line cards, Raman amplifier modules, EDFA amplifier modules, OSC modules, OTDR modules, modems, pluggable modules, pizza boxes, and the like. Also, the integrated polarimeter can be realized in a pluggable module that is configured to plug into another hardware device in the optical line system. These hardware devices are part of the optical line system and operate in an integrated manner. That is, these hardware devices support unified management and control, i.e., Operations, Administration, Maintenance, and Provisioning (OAM&P). The polarimeter 40 is able to operate through this unified management and control as well as in-service with WDM traffic-bearing channels, OSC channels, OTDR signals, and the like. The amplifier 42 can be an EDFA, a Semiconductor Optical Amplifier (SOA), Raman amplifier, or the like. Note, depending on the wavelength of the polarimeter probe signal, the amplifier 42 may require different operating bands from conventional EDFAs. Based on the connectivity of the amplifier 42, the optical line device 32 is configured to loop back an amplified polarimeter probe signal, back to the optical line device 30.

The polarimeter 40 includes a transmitter coupled to the filter 54 and a receiver coupled to the filter 56. Note, generally the polarimeter 40 is a receiving device configured to measure the polarization of a test signal. Those of ordinary skill in the art will recognize the integrated polarimeter described herein includes the receiving device and the transmitter for the test signal, i.e., the polarization probe signal. In an embodiment, the receiver can include any of the various embodiments shown in FIGS. 6-10 . In an embodiment, the transmitter can be a Distributed Feedback Laser (DFB), such as to provide a single polarization, Continuous Wave (CW) or pulse. The transmitter provides the polarization probe signal at a wavelength which does not interfere with the WDM traffic-bearing channels, OSC channels, OTDR signals, and the like. For example, the WDM traffic-bearing channels may be in the C-band, such as about 1528-1560 nm; of course, other transmission bands are also contemplated. Raman pumps are typically below 1500 nm in the 1400 nm range. The OSC channels, the OTDR wavelengths, and the like can be selected not to interfere with one another and the polarization probe signal. For example, the OSC channels can be 1510 nm, 1625 nm, or the like. In an embodiment, the polarization probe signal is at 1591 nm to avoid nonlinear interaction with Raman pumps. Of course, other values are also contemplated for the polarimeter 40 and the polarimeter probe signal, so long as the value does not interfere with other signals in the optical line system. In an embodiment, the polarimeter 40 can share a laser with an OTDR as described herein.

FIG. 4 illustrates the optical line device 34 which is a Raman amplifier with the polarimeter 40 integrated therein along with Raman pumps 60, an OTDR 62, and an OSC 64. The optical line device 34 is a four-port optical device with a line_A_in port 70, a line_A_out port 72, a line_B_out port 74, and a line_B_in port 76. For example, line A could be coupled to the fiber 16 or other optical components, and line B could be coupled to the fiber 18 or other optical components. The Raman amplifier 60 includes one or more Raman pumps 78 which are coupled via a filter 80 to counter-propagate out the line_A_in port 70. The filter can be a 14XX filter where XX is the wavelength in the 1400-1500 nm range for the Raman pumps, or the filter can combine any signal below 1500 nm or the like with other signals above 1500 nm. The OTDR 62 can provide back reflection measurements via a DFB laser 82 and a detector 84, such as an avalanche photodiode. The DFB laser 82 and the detector 84 can be coupled to the line_A_in port 70 via a circulator 86 or the like and a filter 88. In an embodiment, the DFB laser 82 can be 1527 nm; of course, other wavelengths are also contemplated. The OSC 62 can be realized through a pluggable optical transceiver 90 such as a Small Form Factor Pluggable (SFP) or the like. The OSC 62 is both added via a filter 92 and removed via a filter 94 to provide a bi-directional telemetry channel. In an embodiment, the OSC 62 can operate at 1511 nm; of course, other wavelengths are also contemplated.

The polarimeter 40 includes a receiver 100 and a DFB laser 102. Again, the DFB laser 102 provides the test signal, i.e., the polarization probe signal to the line_B_out port 76 via the filter 54 and receives at the receiver 100 a corresponding test signal from the line_A_in port 70 via the filter 56. Again, in an embodiment, the DFB laser 102 can be at 1591 nm; of course, other wavelengths are also contemplated. In this embodiment, the test signal co-propagates with the C-Band for WDM traffic-bearing channels, thereby enabling detection of SOP transients from an upstream polarization probe signal. The receiver 100 contemplates any architecture including the various embodiments described in FIGS. 6-10 . Thus, in the optical line device 34, the Raman amplifier 60, the OTDR 62, the OSC 64, and the polarimeter 40 can operate concurrently as each has a different operating wavelength and each of the operating wavelengths are outside the C-band for WDM traffic-bearing channels.

In FIG. 5 , the optical line device 36 is a pluggable module which can be plugged into the optical line system to support dual OTDR and polarimeter functionality. FIG. 5 illustrates two complementary optical line devices 36 connected to one another such as via the fibers 16, 18. The optical line device 36 is configured to operate either as an OTDR or a polarimeter, based on the configuration of switches 110, 112. Note, both the OTDR and the polarimeter can share a DFB laser 114 which can be configured as a pulse for an OTDR mode or a single polarization Continuous Wave (CW) for an SOP mode. The optical line device 36 includes an output port 120 and an input port 122. The DFB laser 114 is coupled to the switch 110 which couples the DFB laser 114 to the output port 120 for the SOP mode and to the input port 122 via a circulator 124 for the OTDR mode to measure back reflections. The input port 122 is coupled to the circulator 124 which connects to either a polarimeter receiver 100 or an OTDR receiver 126 based on the configuration of the switch 112. In an embodiment, the default operation of the optical line device 36 can be a polarimeter, i.e., the switches 110, 112 connected to the “1” position, with the OTDR mode selectively enabled as needed to measure back reflections.

Integrated Polarimeter

Referring to FIG. 6 , in an embodiment, a block diagram illustrates a Division of Amplitude Polarimeter (DOAP) 200 which may be used for the integrated polarimeter. The DOAP 200 has input light 202 which is variously arranged through different arrangements 204 which output the differently arranged light to four detectors 206 which provide corresponding electrical outputs i₁, i₂, i₃, i₄ 208 which are linear projections of the Stokes Parameters of the input light 202. The different arrangements 204 divides the input light 202 into different ways (commonly 4 ways) with different arrangements so that the output photocurrents of the DOAP 200 are the linear projections of the input light 202 SOP. The key technology of the polarimeter is the element realizing the different arrangements 204 of light. Again, the existing approaches of the different arrangements 204 require special design of the bulk free space optics components or of the special coupling functions of the optical fiber. The complexity in the DOAP 200 is the different arrangements 204, and bulk-free space optics components or of the special coupling functions of the optical fiber are not amenable to integration into the optical line system.

Referring to FIGS. 7-10 , in various embodiments, block diagrams illustrate a novel, low-cost fiber optics-based integrated polarimeters 300A, 300B, 300C, 300D that can be used with and integrated into components of the optical line system. FIG. 7 is a block diagram of the integrated polarimeter 300A with a 45° alignment 302 coupled to a Polarization Maintaining (PM) coupler 304. FIG. 8 is a block diagram of another integrated polarimeter 300B with the 45° alignment 302 moved to a Polarization Beam Splitter (PBS) 306B. FIG. 9 is a block diagram of yet another integrated polarimeter 300C replacing the two Polarization Beam Splitters in the configuration of FIG. 7 with two polarizers 330A, 330B and adding a total power photodetector 206X which is tapped from the input light 202 prior to the PM coupler 304. FIG. 10 is a block diagram of yet another integrated polarimeter 300D with the 45° alignment 302 moved to a polarizer 330B. Note, each of the integrated polarimeters 300 uses passive, off-the-shelf fiber components, lending itself to integration in the optical line system. Further, the integrated polarimeters 300 use the DOAP 200 configuration.

Each of the integrated polarimeters 300 has the input light 202 connected to a PM coupler 304. In FIG. 7 , the input light 202 can include dual polarization light, e.g., X and Y axis or Horizontal and Vertical axis or the like. The PM coupler 304 is configured to split the input light 202 to two identical signals on two outputs 310, 312. The 45° alignment 302 is coupled to the output 302 and configured to rotate the light on the output 312 by 45°. Each of the outputs 310, 312 include PM fiber 320, 322 which maintain the polarization of the light on the outputs 310, 312. The PM fiber 320 is connected to a PBS 306A which splits light on the output 310 into two polarizations, each provided to a PD 206A, 206B to provide the corresponding electrical outputs i₁, i₂ 208. The PM fiber 322 is connected to the PBS 306B which splits the 45° rotated light into two polarizations, each provided to a PD 206C, 206D to provide the corresponding electrical outputs i₃, i₄ 208.

The polarization axes of the PM fiber 320 at the output 310 of the PM coupler 304 is 0 degree aligned with the polarization axes of the input signal 202. Therefore, the output of the PBS 306A in the upper arm, i₁ and i₂, are proportional to the signal power on X-pol and Y-pol. The PM fiber 322 at the output 312 of the PM coupler 304 is 45° degree aligned with the polarization axes of the input signal 202. Therefore, after the following PBS 306B, i₃ and i₄ are proportional to the signal power on the two polarization axes, which are 45° degree rotated from the polarization axes of the input signal 202. SOP and SOP transient speed can be subsequently calculated by i₁˜i₄ using Eq. 1˜8, where |Ex| and |Ey| are the intensity of the signal on the two polarization axes, Δφ is the phase delay between the signal on the two polarization axes at the Polarimeter input, Δt is the sampling time interval.

$\begin{matrix} {i_{1} = {❘E_{x}❘}^{2}} & (1) \end{matrix}$ $\begin{matrix} {i_{2} = {❘E_{y}❘}^{2}} & (2) \end{matrix}$ $\begin{matrix} {i_{3} = {{\frac{1}{2}\left( {{❘E_{x}❘}^{2} + {❘E_{y}❘}^{2}} \right)} + {\cos{\Delta\varphi}{❘E_{x}❘}{❘E_{y}❘}}}} & (3) \end{matrix}$ $\begin{matrix} {i_{4} = {{\frac{1}{2}\left( {{❘E_{x}❘}^{2} + {❘E_{y}❘}^{2}} \right)} - {\cos\Delta\varphi{❘E_{x}❘}{❘E_{y}❘}}}} & (4) \end{matrix}$ $\begin{matrix} {S_{1} = {{{❘E_{x}❘}^{2} - {❘E_{y}❘}^{2}} = {i_{1} - i_{2}}}} & (5) \end{matrix}$ $\begin{matrix} {S_{2} = {{2{❘E_{x}❘}{❘E_{y}❘}\cos\Delta\varphi} = {i_{3} - i_{4}}}} & (6) \end{matrix}$ $\begin{matrix} {S_{3} = {{2{❘E_{x}❘}{❘E_{y}❘}\sin{\Delta\varphi}} = \sqrt{{4i_{1}i_{2}} - \left( {i_{3} - i_{4}} \right)^{2}}}} & (7) \end{matrix}$ SOP transient speed=Angular Deflection Between ([S1(n), S2(n), S3(n)]) and ([S1(n+1), S2(n+1), S3(n+1)])/Δt  (8)

The integrated polarimeters 300B, 300C, 300D are variants of the integrated polarimeter 300A, which can provide additional cost benefits while trading off some performance or functionality, which is acceptable in the optical line system application. The integrated polarimeter 300B moves the 45° alignment 302 from the output 312 of the PM coupler 304 to the input of the PBS 306B, in order to avoid the extra cost for a special configuration of the PM coupler 304. Note, a PBS with 45° alignment at the input is readily available while a PM coupler with 45° alignment requires customization. For this version to be working, the PM fiber 322 between the second output of PM coupler and the PBS has to be as short as possible to eliminate the fast change of birefringence, which will introduce error to SOP tracking of the input light 202.

The integrated polarimeter 300C replaces the two PBSs 306A, 306B with two polarizers 330A, 330B. Assuming 100% Degree of Polarization (DOP) of the input light 202, the two outputs of the PBS 306A, 306B are complementary. Therefore, i₂ and i₄ can be derived by subtracting i₁ and i₃ from the total power which is obtained from a detector 206X which is tapped from the input light 202 prior to the PM coupler 304. The integrated polarimeter 300C is less expensive since the polarizers 330 are a lower cost than the PBSs 306. In addition, the integrated polarimeter 300C reduces the amount of high speed high dynamic range receivers (the detectors 206) by 2, which will not only reduce the cost but also reduce the complexity of the electrical circuit for the synchronization, data transmission as well as data storage. For the integrated polarimeter 300C to work, the input light 202 has to be 100% polarized. Note, the integrated polarimeter 300C cannot measure DOP.

The integrated polarimeter 300D is a combination of the integrated polarimeter 300B, 300C. Specifically, the integrated polarimeter 300D is similar to the integrated polarimeter 300C with the polarizers 330 with the 45° alignment 302 from the output 312 of the PM coupler 304 to the input of the polarizer 330B.

Referring to FIG. 11 , in an embodiment, a 2D graph illustrates values of the electrical outputs i₁, i₂, i₃, i₄ 208 from the DOAP 200 and the integrated polarimeter 300. It is noted that all of the integrated polarimeters 300 can only measure the shape of a polarization ellipse 400, but not its direction of rotation, i.e., cannot distinguish between right-handed or left-handed polarization. However, with a faster than Nyquist sampling rate after the receiver, the proposed polarimeter 300 will be able to track the transition of the polarization ellipse during the change of rotating direction. Therefore, it is still able to serve the purpose of fast SOP transient detection. The electrical outputs i₁, i₂ measure the power on the X and Y polarizations while the electrical outputs i₃, i₄ measure how “fat” the polarization ellipse 400 is. The integrated polarimeters 300 cannot measure the direction of the circular polarization, i.e., can only project SOP on half of the Poincare sphere. Output: i ₁ =a ₁ |Ex|2; i ₂ =a ₂ |Ey|2; i ₃ =a ₃(sin 45o|Ey|2+cos 45o|Ex|2+cos Δφ|Ex||Ey|); i ₄ =a ₄(sin 45o|Ex|2+cos 45o|Ey|2−cos Δφ|Ex||Ey|); SOP: S1=|Ex|2−|Ey|2 S2=2|Ex||Ey|cos Δφ S3=2|Ex||Ey|sin Δφ

The integrated polarimeter 300 can compute cos Δφ by i1˜i4, and sin Δφ is computed by sin Δφ=sqrt(1−cos Δφ²). Thus, the integrated polarimeter 300 cannot tell the “sign” of sin Δφ. Therefore, S3 can only be projected on the positive side. However, in the optical line application, the objective is to measure SOP speed instead of absolute SOP. The integrated polarimeter 300 is able to accurately measure the SOP speed.

Referring to FIG. 12 , in an embodiment, graphs in a table illustrate measurements with the integrated polarimeter 300 for linearly polarized light on a slow axis, polarization transforming between 45° linear polarization and circular polarization, and randomly rotating polarization with a polarization scrambler. Referring to FIG. 13 , in an embodiment, graphs illustrate measurements taken by the integrated polarimeter 300 relative to a commercial, external polarimeter to detect a mechanical shock applied to the optical line system. Referring to FIG. 14 , in an embodiment, graphs illustrate measurements taken by the integrated polarimeter 300 relative to a commercial, external polarimeter to detect hot air applied to the optical line system. Note, in both FIGS. 13 and 14 , the integrated polarimeter 300 provides similar performance to the commercial, external polarimeter.

Two Fiber Mode Example Setup with the Optical Line Devices 30, 32

Referring to FIG. 15 , in an embodiment, a network diagram illustrates an example setup for a two-fiber mode in a loopback configuration 500 with the integrated polarimeter to localize the SOP transients. The loopback configuration 500 is described in commonly-assigned U.S. patent application Ser. No. 14/865,802 filed Sep. 25, 2015, and entitled “SYSTEMS AND METHODS USING A POLARIMETER TO LOCALIZE STATE OF POLARIZATION TRANSIENTS ON OPTICAL FIBERS.” The loopback configuration 500 can include the optical line device 30 at the node 12 and the optical line device 32 at the node 12. The node 14 includes a polarized source 102 coupled to the fiber 16; a loop back via the amplifier 42 at the node 12 configured to connect the fiber 16 to the fiber 18; and the polarimeter 40, 100, 300 at an end of the fiber 18. A transient 502 occurring on or associated with the bundle 20 carrying both the fibers 16, 18 will thus be observed as two distinct transient excursions at the polarimeter 40, 100, 300. The first observation will propagate from the transient impact of the fiber 18. The transient impact of the fiber 16 will propagate to the amplifier 42, and then along the full length of the fiber 18 to the polarimeter 40, 100, 300, appearing as a second transient on the polarimeter 40, 100, 300. The time difference between these two observed transients is the optical signal propagation time between the SOP transient source on the fiber 16 and the SOP transient source on the fiber 18. This fact allows a determination of the distance of the SOP transient source from the amplifier 42, effectively localizing the SOP transient source.

It will be appreciated that some embodiments described herein may include one or more generic or specialized processors (“one or more processors”) such as microprocessors; Central Processing Units (CPUs); Digital Signal Processors (DSPs): customized processors such as Network Processors (NPs) or Network Processing Units (NPUs), Graphics Processing Units (GPUs), or the like; Field Programmable Gate Arrays (FPGAs); and the like along with unique stored program instructions (including both software and firmware) for control thereof to implement, in conjunction with certain non-processor circuits, some, most, or all of the functions of the methods and/or systems described herein. Alternatively, some or all functions may be implemented by a state machine that has no stored program instructions, or in one or more Application Specific Integrated Circuits (ASICs), in which each function or some combinations of certain of the functions are implemented as custom logic or circuitry. Of course, a combination of the aforementioned approaches may be used. For some of the embodiments described herein, a corresponding device such as hardware, software, firmware, and a combination thereof can be referred to as “circuitry configured or adapted to,” “logic configured or adapted to,” etc. perform a set of operations, steps, methods, processes, algorithms, functions, techniques, etc. as described herein for the various embodiments.

Moreover, some embodiments may include a non-transitory computer-readable storage medium having computer readable code stored thereon for programming a computer, server, appliance, device, processor, circuit, etc. each of which may include a processor to perform functions as described and claimed herein. Examples of such computer-readable storage mediums include, but are not limited to, a hard disk, an optical storage device, a magnetic storage device, a ROM (Read Only Memory), a PROM (Programmable Read Only Memory), an EPROM (Erasable Programmable Read Only Memory), an EEPROM (Electrically Erasable Programmable Read Only Memory), Flash memory, and the like. When stored in the non-transitory computer readable medium, software can include instructions executable by a processor or device (e.g., any type of programmable circuitry or logic) that, in response to such execution, cause a processor or the device to perform a set of operations, steps, methods, processes, algorithms, functions, techniques, etc. as described herein for the various embodiments.

Although the present disclosure has been illustrated and described herein with reference to preferred embodiments and specific examples thereof, it will be readily apparent to those of ordinary skill in the art that other embodiments and examples may perform similar functions and/or achieve like results. All such equivalent embodiments and examples are within the spirit and scope of the present disclosure, are contemplated thereby, and are intended to be covered by the following claims. 

What is claimed is:
 1. A management system for an optical line system, the management system comprising: one or more processors and memory storing instructions that, when executed, cause the one or more processors to receive State of Polarization (SOP) measurements from one or more optical components in the optical line system, wherein the SOP measurements are taken while traffic-bearing channels are operating, monitor health of one or more fibers based on the SOP measurements, and provide the health of the one or more fibers to enable one or more of 1) configuring a transmitter for use on the one or more fibers, 2) selecting a type of transmitter for use on the one or more fibers, 3) selecting a type of receiver for use on the one or more fibers, 4) configuring a receiver for use on the one or more fibers, and 5) determining whether to restore a failed connection from another fiber to the one or more fibers.
 2. The management system of claim 1, wherein the health includes detection and/or localization of SOP transients.
 3. The management system of claim 1, wherein the memory storing instructions that, when executed, further cause the one or more processors to store historical SOP measurements, and monitor the health of the one or more fibers over time based on current SOP measurements and the historical SOP measurements.
 4. The management system of claim 3, wherein the memory storing instructions that, when executed, further cause the one or more processors to determine SOP tracking values based on SOP transients detected in the historical SOP measurements.
 5. The management system of claim 1, wherein a polarization probe signal for the SOP measurements co-propagates with the traffic-bearing channels, for detection of an SOP transient.
 6. The management system of claim 5, wherein a wavelength of the polarization probe signal is outside of the C-band, greater than 1500 nm to avoid Raman pump lasers, and different from wavelengths for Optical Supervisory Channels (OSCs).
 7. The management system of claim 1, wherein the one or more optical components include one or more of a Raman amplifier module, an Erbium Doped Fiber Amplifier (EDFA) module, an Optical Supervisory Channel (OSC) module, an Optical Time Domain Reflectometer (OTDR) module, a modem, and a pluggable module configured to plug into any of the foregoing modules.
 8. A method comprising steps of: receiving State of Polarization (SOP) measurements from one or more optical components in an optical line system, wherein the SOP measurements are taken while traffic-bearing channels are operating, and monitoring health of one or more fibers based on the SOP measurements; and providing the health of the one or more fibers for enabling one or more of 1) configuring a transmitter for use on the one or more fibers, 2) selecting a type of transmitter for use on the one or more fibers, 3) selecting a type of receiver for use on the one or more fibers, 4) configuring a receiver for use on the one or more fibers, and 5) determining whether to restore a failed connection from another fiber to on the one or more fibers.
 9. The method of claim 8, wherein the health includes detection and/or localization of SOP transients.
 10. The method of claim 8, wherein the steps further include storing historical SOP measurements, and monitoring the health of the one or more fibers over time based on current SOP measurements and the historical SOP measurements.
 11. The method of claim 10, wherein the steps further include determining SOP tracking based on SOP transients detected in the historical SOP measurements.
 12. The method of claim 8, wherein a polarization probe signal for the SOP measurements co-propagates with the traffic-bearing channels, for detection of an SOP transient.
 13. The method of claim 12, wherein a wavelength of the polarization probe signal is outside of the C-band, greater than 1500 nm to avoid Raman pump lasers, and different from wavelengths for Optical Supervisory Channels (OSCs).
 14. The method of claim 8, wherein the one or more optical components include one or more of a Raman amplifier module, an Erbium Doped Fiber Amplifier (EDFA) module, an Optical Supervisory Channel (OSC) module, an Optical Time Domain Reflectometer (OTDR) module, a modem, and a pluggable module configured to plug into any of the foregoing modules.
 15. A non-transitory computer-readable medium comprising instructions that, when executed, cause on or more processors to perform steps of: receiving State of Polarization (SOP) measurements from one or more optical components in an optical line system, wherein the SOP measurements are taken while traffic-bearing channels are operating, monitoring health of one or more fibers based on the SOP measurements, and providing the health of the one or more fibers for enabling one or more of 1) configuring a transmitter for use on the one or more fibers, 2) selecting a type of transmitter for use on the one or more fibers, 3) selecting a type of receiver for use on the one or more fibers, 4) configuring a receiver for use on the one or more fibers, and 5) determining whether to restore a failed connection from another fiber to the one or more fibers.
 16. The non-transitory computer-readable medium of claim 15, wherein the health includes detection and/or localization of SOP transients.
 17. The non-transitory computer-readable medium of claim 15, wherein the steps further include storing historical SOP measurements, and monitoring the health of the one or more fibers over time based on current SOP measurements and the historical SOP measurements.
 18. The non-transitory computer-readable medium of claim 17, wherein the steps further include determining SOP tracking based on SOP transients detected in the historical SOP measurements.
 19. The non-transitory computer-readable medium of claim 15, wherein a polarization probe signal for the SOP measurements co-propagates with the traffic-bearing channels, for detection of an SOP transient.
 20. The non-transitory computer-readable medium of claim 19, wherein a wavelength of the polarization probe signal is outside of the C-band, greater than 1500 nm to avoid Raman pump lasers, and different from wavelengths for Optical Supervisory Channels (OSCs). 